Circuit configuration for monitoring and/or regulating supply voltages

ABSTRACT

The invention relates to a circuit configuration for monitoring and/or for regulating supply voltages. Said circuit enables at least two supply voltages (U 12 ) or (U 22 ) that are produced by means of two feed-ins (Q 1,  Q 2 ) and that are provided for consumer circuits (V 1,  V 2 ) to be monitored and limited simultaneously. To this end, the circuit configuration comprises a corresponding voltage monitoring electronics unit ( 1 ) which detects the supply voltages (U 12 , U 22 ) and compares them with associated tolerance values (ΔU 12 , ΔU 22 ). The voltage monitoring electronics unit ( 1 ) also provides a control signal (y) which signals whether the first supply voltage (U 12 ) is lower than the associated tolerance value (ΔU 12 ). The control signal (y) is used to control a shunt electronics unit ( 2 ) through which a shunt current (I S ) passes temporarily. Said shunt current (I S ) is fed by feed-in (Q 1 ) and by feed-in (Q 2 ) and passes through the shunt electronics unit ( 2 ) at least when the control signal (y) signals that at least the supply voltage (U 12 ) is greater than the associated tolerance value (ΔU 12 ).

[0001] The invention relates to a circuit configuration for monitoring and/or regulating and in particular limiting at least two supply voltages for consumer circuits.

[0002] Electronic consumer circuits, in particular those used is areas at risk of fire and/or explosions, are typically protected by means of voltage limiters from excessive elevations of initially applied voltages, or in other words overvoltages that would increase beyond the voltage level permitted for a given circuit.

[0003] Circuit configurations that have at least one semiconductor element, connected in a shunt to the input voltage of a downstream consumer circuit and having a variable ohmic resistor, are often used as voltage limiters.

[0004] For instance, in U.S. Pat. Nos. 4,589,049 and 4,849,845, circuit configurations for monitoring and/or regulating, in particular limiting, a supply voltage for a downstream consumer circuit are described that include the following:

[0005] a voltage monitoring electronics unit, reacting the supply voltage, for generating a control signal that signals whether the supply voltage is lower than an associated tolerance value;

[0006] a shunt electronics unit, triggered by the control signal, with at least one semiconductor element for regulating and guiding a shunt current driven by the supply voltage,

[0007] and the supply voltage drops at least in part via the shunt electronics unit, and

[0008] the shunt current flows through the shunt electronics unit at least whenever the control signal signals that the supply voltage is greater than the tolerance value.

[0009] When such circuit configurations, serving as active voltage limiters, are used for electronic consumer circuits that are used in areas at risk of fire and/or explosion, particular in circuits that are intended to meet European standards EN 50019 and/or EN 50020, at least the voltage-limiting shunts are made redundant, for instance by means of multiple cascading, in terms of current-carrying capacity and/or voltage strength, because of the required enhanced or intrinsic safety.

[0010] This in turn necessarily means increased expense for components and/or wiring, and typically this also means an increased demand for space for such voltage limiters.

[0011] It is therefore an object of the invention to reduce the expense for circuitry for a voltage limiter of this kind, and especially the expense for circuitry for the voltage-limiting shunt.

[0012] For attaining this object, the invention comprises a circuit configuration for monitoring and/or regulating at least one first supply voltage, generated by means of a first feed-in, for a first consumer circuit connected to a first output of the circuit configuration, and at least one second supply voltage, generated by means of a second feed-in, for a second consumer circuit connected to a second output of the circuit configuration, which circuit configuration includes:

[0013] a voltage monitoring electronics unit, reacting to at least the first supply voltage, for generating a control signal that signals whether the first supply voltage is lower than an associated first tolerance value; and

[0014] a shunt electronics unit, through which a shunt current flows at least intermittently;

[0015] wherein the shunt current

[0016] is supplied by the first and the second feed-in, and

[0017] flows through the shunt electronics unit at least whenever the control signal signals that at least the first supply voltage is greater than the first tolerance value.

[0018] In a first preferred feature of the invention, the voltage monitoring electronics unit also reacts to the at least second supply voltage; and the control signal signals whether the second supply voltage is lower than an associated second tolerance value.

[0019] In a second preferred feature of the invention, the shunt electronics unit includes at least one controllable semiconductor element.

[0020] In a third preferred feature of the invention, a conductivity of the semiconductor element is regulated by means of the control signal.

[0021] In a fourth preferred feature of the invention, the circuit configuration includes means for keeping potentials of the first and second supply voltages separate.

[0022] In a fifth preferred feature of the invention, the first feed-in furnishes a first terminal voltage for regulating the first supply voltage, and reacts to an increase in the shunt current by lowering the first terminal voltage.

[0023] In a sixth preferred feature of the invention, the control signal signals the extent to which the first supply voltage is higher than the first tolerance value.

[0024] In a seventh preferred feature of the invention, at least the first consumer circuit is of intrinsic and/or enhanced safety.

[0025] The invention is based on the inventors' discovery that in an electronic circuit with multiple feeds by means of such lines, such as a circuit connected to a data bus, if a fault and in particular an overvoltage occurs on even only one of the bus lines, the entire circuit must often be rendered voltageless, for instance by shutting it off or by lowering the voltages supplying the circuit, since continued operation of circuit components that are not connected to the faulty bus lines is either unnecessary or not allowed.

[0026] It is a fundamental concept of the invention, whenever an overvoltage is detectable on at least one of a plurality of voltage-carrying lines, to pull these lines simultaneously to a lower potential, such as a ground potential of the circuits furnishing the applicable voltage, and thus to render downstream circuits practically voltageless, by means of a single circuit configuration that is in a shunt, i.e. a parallel circuit, to each of these lines.

[0027] One advantage of the circuit configurations of the invention is that by their use at the entrance to an electronic circuit, especially one of intrinsic and/or enhanced safety, the expense for components for realizing the voltage-limiting shunts can be reduced considerably. It has in fact been found that the power consumption capability of the semiconductor elements that carry the shunt current, and in particular their current-carrying capacity, that is required to achieve the necessary safety can be designed to be considerably less than what would result in a version with separately embodied shunts for each line and additionally with the then-necessary power consumption capability of each individual semiconductor element. Another reason why this is true is that in the circuit configurations of the invention, the semiconductor element or elements can be cooled more effectively compared to the other version. Moreover, to achieve the shunt electronics unit, even without higher-precision semiconductor elements, for instance, which typically have a higher individual price, can be used without increasing the total cost of the circuit configuration.

[0028] The invention and further advantages will be described in further detail below in conjunction with exemplary embodiments that are shown in the drawings; in the drawings, identical elements are identified by the same reference numerals. If it is helpful for the sake of simplicity, reference numerals already assigned are omitted from subsequent drawing figures.

[0029]FIG. 1 shows one exemplary embodiment of a circuit configuration for limiting voltages;

[0030]FIG. 2 shows another exemplary embodiment of a circuit configuration for limiting voltages; and

[0031]FIG. 3 shows one example of a cascaded combination of a plurality of circuit configurations for limiting voltages.

[0032]FIGS. 1 and 2 each schematically show one exemplary embodiment for a circuit configuration that serves in operation to monitor a first supply voltage U₁₂ for a first consumer circuit V1, connected to a first output 11, and a second supply voltage U₂₂ for a second consumer circuit V2, connected to a second output 21. The consumer circuits V1, V2 can for instance be transmitter circuits of field devices with enhanced or intrinsic safety.

[0033] The supply voltages U₁₂, U₂₂ are preferably direct voltages and are furnished by a first feed-in Q1 and a second feed-in Q2, respectively, and in the exemplary embodiments of FIGS. 1 and 2 they are practically equal to a first terminal voltage U₁₁ and second terminal voltage U₁₂ that can be picked up at the output of the feed-in Q1 and Q2, respectively. However, the terminal voltages U₁₁, U₂₁ and the corresponding supply voltages U₁₂, U₂₂ can differ from one another, for instance because of longitudinal voltage instances along connecting lines that extend between the feed-ins Q1, Q2 and the respective associated consumer circuits V1 and V2.

[0034] Both terminal voltages U₁₁, U₂₁ can have not only a respective rated voltage component but also an error voltage component, in particular an overvoltage. Thus the two supply voltages U₁₂, U₂₂ are also composed both of a voltage component assumed to be constant and a voltage component assumed to be variable, in particular one that appears only temporarily, namely a rated voltage U_(n12) and an error voltage U_(f12) for the supply voltage U₁₂, and a rated voltage U_(n22) and an error voltage U_(f22) for the supply voltage U₂₂. Accordingly, for the supply voltages U₁₂, U₂₂, the following equations can apply, respectively:

U ₁₂ ≦U _(n12) +U _(f12),   (1)

[0035] and

U ₂₂ ≦U _(n22) +U _(f22).

[0036] For monitoring the supply voltages U₁₂, U₂₂, the circuit configuration of FIG. 1 has a corresponding voltage monitoring electronics unit 1, which in operation detects the supply voltages U₁₂, U₂₂ and replicates them in a control signal y, such as a binary or analog signal voltage, which signals whether the supply voltage U₁₂ is lower than a tolerance value ΔU₁₂ associated with it, and whether the supply voltage U₂₂ is lower than a tolerance value ΔU₂₂ associated with it, or whether at least one of the supply voltages U₁₂, U₂₂ is higher than the respective associated tolerance value ΔU₁₂ and ΔU₂₂.

[0037] The tolerance value ΔU₁₂ is regulated such that it is greater than or equal to a highest expected voltage level Max{U₁₂(U_(f12)=0)} of the supply voltage U₁₂ without interference, at which the error voltage U_(f12) is equal to zero. The tolerance value ΔU₁₂ is also regulated such that it is less than a least voltage level Min{U₁₂(U_(f12)>0)} the supply voltage U₁₂ with interference, at which the error voltage U_(f12) is greater than zero; the tolerance value ΔU₂₂ should be regulated analogously relative to the supply voltage U₂₂. For the tolerance values ΔU₁₂, ΔU₂₂, the following equations thus respectively apply:

Max{U ₁₂(U _(f12)=0)}≦ΔU ₁₂<Min{U ₁₂(U _(f12)>0)}  (2)

[0038] and

Max{U ₂₂(U _(f22)=0)}≦ΔU ₂₂<Min{U ₂₂(U _(f22)>0)}.

[0039] Besides detecting the supply voltages U₁₂, U₂₂, the circuit configuration also serves to limit the supply voltages U₁₂, U₂₂ in their voltage level, specifically such that they do not exceed the respective associated tolerance value ΔU₁₂ and ΔU₂₂, or at most exceed it for no longer than approximately 100 ns.

[0040] For regulating the supply voltages U₁₂, U₂₂, the circuit configuration furthermore includes a shunt electronics unit 2, with at least one semiconductor element that is adjustable in its conductivity and that when triggered by the control signal y in operation varies this conductivity.

[0041] The shunt electronics unit 2, together with the consumer circuits V1, V2 downstream of the circuit configuration, functions as an adjustable current divider, comprising a variable output resistor for the circuit configuration and an input resistor for the consumer circuit V1, and an input resistor for the consumer circuit V2. By means of the shunt electronics unit 2, the supply voltages U₁₂, U₂₂ dropping across it are limited in their level or are lowered again, in particular for an error situation in which at least one of the supply voltages U₁₂, U₂₂ is greater than the associated tolerance value ΔU₁₂ or ΔU₂₂.

[0042] Moreover, the shunt electronics unit 2 at least intermittently, and in particular in the above-described error situation, experiences a flow through it of a shunt current Is of the circuit configuration. As shown in FIG. 1, the shunt current I_(S) is equivalent to a total current that is formed by means of a first partial current I_(S1), driven by the supply voltage U₁₂, and a second partial current I_(S2) driven by the supply voltage U₂₂. The shunt current I_(S) in particular also serves to increase the current demand at the first and/or second feed-in Q1, Q2, and thus at least briefly to lower the supply voltage U₁₂ and the supply voltage U₂₂, respectively.

[0043] The shunt electronics unit 2, as shown in FIG. 1, includes at least one controllable semiconductor element 21, located in shunt with the outputs 12, 22, and the control signal y is applied to the semiconductor element at a corresponding control electrode. A bipolar transistor or a field effect transistor can for instance serve as the semiconductor element 21. If necessary, the single semiconductor element 21 can also be replaced with a corresponding Darlington circuit of a plurality of transistors, to improve the response performance of the shunt electronics unit 2 to the control signal y.

[0044] To increase its current-carrying capacity, the shunt electronics unit 2 can moreover be provided with a corresponding cooling assembly 22, such as a cooling baffle at the semiconductor element 21, by way of which a considerable proportion ΔP of the power picked up by the semiconductor element 2, whose level can be estimated for instance using the relationship U₁₂I_(S1)+U₂₂I_(S2) can be dissipated to the environment. Moreover, the power consumption capability can also be increased by providing that the shunt electronics unit 2, instead of a single transistor, has a parallel circuit of two or more transistors, especially of the same type.

[0045] As shown in FIG. 1, the circuit configuration furthermore includes means 3 for keeping potentials separate, which means serve to keep at least one potential of the supply voltage U₁₂ separate from at least one potential of the supply voltage U₂₂.

[0046] The means 3 for keeping potentials separate, in the exemplary embodiment of FIG. 1, include a first diode D1 for the supply voltage U₁₂, which carries the at least intermittently flowing partial current I_(S1), and a second diode D2 for the supply voltage U₂₂, carrying the at least intermittently flowing partial current I_(S2). As FIG. 1 shows, a potential of the supply voltage U₁₂ is applied to the diode D1 via a first electrode, and a potential of the supply voltage U₂₂ is applied to the diode D2 via its first electrode, while the diodes D1, D2 are connected to one another each via their respective second electrodes. The diodes D1, D2 are connected such that in the error situation described above, they experience a flow in the conducting direction of the partial current I_(S1) and I_(S2), respectively; however, a charge compensation between the two potentials of the supply voltages U₁₂, U₂₂ that are supposed to be kept separate from one another is practically always prevented. If necessary, instead of a single diode D1 or D2, a respective series circuit and/or parallel circuit, functioning in the same way, of two or more diodes can be used to separate the potentials.

[0047] In a preferred feature of the invention, the voltage monitoring electronics unit 1, as shown in FIG. 1, is realized by means of a first comparator Kp1 for the supply voltage U₁₂ and a second comparator Kp2 for the supply voltage U₂₂; the comparators Kp1, Kp2 are connected to one another on the output side. For detecting the supply voltages U₁₂, U₂₂, partial voltages k₁U₁₂ and k₂U₂₂ proportional to them are applied respectively to noninverting inputs of one operational amplifier of each of the comparators Kp1, Kp2. A reference voltage k₁ΔU₁₂ and k₂ΔU₂₂ that is proportional to the corresponding tolerance value ΔU₁₂ or ΔU₂₂ is also applied to their respective inverting input of these operational amplifiers.

[0048] Since the two comparators Kp1, Kp2 are connected to one another on the output side, the voltage monitoring electronics unit 1 furnishes a signal voltage, which serves as a binary control signal y and corresponds to a logical-disjunctive linkage of the likewise binary output voltages of the two comparators Kp1, Kp2. Accordingly, the control signal y assumes a high level for a logical “1” when the output voltage of the first and/or comparator Kp1, Kp2 also has a high level, or in other words if the supply voltage U₁₂ is higher than the tolerance value ΔU₁₂, and/or if the supply voltage U₂₂ is higher than the tolerance value ΔU₂₂; if not, the control signal y has a low level for logical “0”.

[0049] In this feature of the invention, the shunt electronics unit 2 in shunt with the outputs 12, 22 preferably has an npn bipolar transistor, acting as a controllable semiconductor element 21, to which the control signal y is supplied in the form of a base-to-emitter voltage.

[0050] If necessary, instead of the comparators Kp1, Kp2, amplifier circuits can be used, of the kind that in contrast to binary output voltages generate analog output voltages, for instance, so that the voltage monitoring electronics unit 1 correspondingly furnishes a likewise analog control signal y. Such amplifier circuits can be configured in a way that is familiar to one skilled in the art, for instance as proportional amplifiers, or as differentiators that detect the error voltages by way of changes in the supply voltages U₁₂, U₂₂. In the latter case, the tolerance values ΔU₁₂, ΔU₂₂ would accordingly represent a reference for changes in voltage over time.

[0051] In a further preferred feature of the invention, the voltage monitoring electronics unit 1, for detecting the supply voltages U₁₂, U₂₂, has a first voltage divider, which is adjustable in operation, for the supply voltage U₁₂ and a second voltage divider, also adjustable in operation, for the supply voltage U₂₂. For that purpose, as shown in FIG. 2, a partial voltage k₁U₁₂ proportional to the supply voltage U₁₂ is applied to a reference electrode of an adjustable Zener diode ZD1 of the first voltage divider, and a partial voltage k₂U₂₂ proportional to the supply voltage U₂₂ is applied to a reference electrode of an adjustable Zener diode ZD2 of the second voltage divider.

[0052] By way of example, adjustable precision Zener diodes made by ZETEX of Type ZR431 can be used as the adjustable Zener diodes ZD1, ZD2.

[0053] The Zener diode ZD1 is preferably applied, by means of its cathodes and via a first current limiting resistor Rl, to a potential of the supply voltage U₁₂; analogously, as shown in FIG. 2, the Zener diode ZD2 can be carried, by means of a second current limiting resistor R2, to a potential of the supply voltage U₂₂. The Zener diodes ZD1, ZD2 are also connected on the cathode side to a third and fourth current limiting resistor R3, R4, respectively. Moreover, the means 3 for keeping potentials separate, in the exemplary embodiment of FIG. 2, include a third diode D3, connected to the current limiting resistor R3 on the anode side, and a fourth diode D4, connected to the current limiting resistor R4 on the anode side. Both the current limiting resistors R3, R4 and the current limiting resistors R1, R2 can be selected such that are within a range of 10 kΩ to 100 kΩ, for instance. However, if necessary, either one of the two or both current limiting resistors R1, R2 can be designed as much larger or can be omitted entirely.

[0054] The two diodes D3, D4 are furthermore connected via their respective cathodes to the control electrode of the shunt electronics unit 2. This shunt electronics unit preferably has a pnp bipolar transistor in shunt with the outputs 12, 22. If the supply voltages U₁₂, U₂₂ differ from one another only slightly, however, it is optionally possible. to dispense with their decoupling by means of the two diodes D3, D4 entirely, so that the Zener diodes ZD1, ZD2 are coupled practically directly, via the current limiting resistor R3 and R4, respectively, to the control electrode of the shunt electronics unit 2.

[0055] In operation of the circuit configuration, voltage drops that are inversely proportional to the partial voltages k₁U₁₂ and k₂U₂₂, respectively, can be picked up via the Zener diodes ZD1, ZD2. These voltage drops, because of the common connection of the Zener diodes ZD1, ZD2 to the control electrode of the shunt electronics unit 2, are in turn disjunctively linked to one another, so that at the control electrode, a signal voltage acting as an analog control signal y which is lower, the higher the supply voltages U₁₂ and/or U₂₂ are, is established or regulated; in other words, this control signal can serve to signal the extent to which the supply voltage U₁₂ is higher than the tolerance value ΔU₁₂ and/or the extent to which the supply voltage U₂₂ is higher than the tolerance value ΔU₂₂.

[0056] In the event that at most the supply voltages U₁₂, U₂₂ are regulated to be equal to the associated tolerance values ΔU₁₂ and ΔU₂₂, or in other words for a normal operating situation, a control current flowing through a diode ZD1 or ZD2 can amount to a few microamperes, for instance being in the range from 10 μA to 100 μA; for the error or fault situation described above, by comparison, the control current can amount to as high as 100 mA.

[0057] This feature of the invention has the particular advantage that because of the quasi-continuously flowing control current acting as a control signal y, it is possible even at low error voltages U_(f12), U_(f22) to achieve a counteraction in which the terminal voltages U₁₁ and U₂₁ that drive the error voltages U_(f12), U_(f22), because of the typically limited power of the feed-ins Q1, Q2, are lowered at least in part again practically without delay.

[0058] This feature of the invention has the further advantage that in the error situation, the control signal y and thus also the shunt current I_(S) can increase slowly and continuously, thus making it possible to suppress or avoid and induction of further overvoltages.

[0059] To increase the redundance of the voltage limitation, it is also possible, as shown schematically in FIG. 3, to connect a plurality of such circuit configurations in series in cascade. It is also possible, parallel to the two supply voltages U₁₂, U₂₂, as schematically represented by the components drawn in dotted lines, it is also possible for still other such supply voltages to be monitored and correspondingly jointly limited by means of a circuit configuration of this kind. 

1. A circuit configuration for monitoring and/or regulating at least one first supply voltage (U₁₂), generated by means of a first feed-in (Q1), for a first consumer circuit (V1) connected to a first output (12) of the circuit configuration, and at least one second supply voltage (U₂₂), generated by means of a second feed-in (Q2), for a second consumer circuit (V2) connected to a second output (22) of the circuit configuration, which circuit configuration includes: a voltage monitoring electronics unit (1), reacting to at least the first supply voltage (U₁₂), for generating a control signal (y) that signals whether the first supply voltage (U₁₂) is lower than an associated first tolerance value (ΔU₁₂); and a shunt electronics unit (2), through which a shunt current (I_(S)) flows at least intermittently; wherein the shunt current (I_(S)) is supplied by the first and the second feed-in (Q1, Q2), and flows through the shunt electronics unit (2) at least whenever the control signal (y) signals that at least the first supply voltage (U₁₂) is greater than the first tolerance value (ΔU₁₂).
 2. The circuit configuration of claim 1, in which the voltage monitoring electronics unit (1) also reacts to the at least second supply voltage (U₂₂); and in which the control signal (y) signals whether the second supply voltage (U₂₂) is lower than an associated second tolerance value (ΔU₂₂).
 3. The circuit configuration of claim 1 or 2, in which the shunt electronics unit (2) includes at least one controllable semiconductor element (21).
 4. The circuit configuration of claim 3, in which a conductivity of the semiconductor element (21) is regulated by means of the control signal (y).
 5. The circuit configuration of one of claims 1-4, which includes means (3) for keeping potentials of the first and second supply voltages (U₁₂, U₂₂) separate.
 6. The circuit configuration of one of claims 1-5, in which the first feed-in (Q1) furnishes a first terminal voltage (U₁₁) for regulating the first supply voltage (U₁₂), and reacts to an increase in the shunt current (I_(S)) by lowering the first terminal voltage (U₁₁).
 7. The circuit configuration of one of claims 1-6, in which the control signal (y) signals the extent to which the first supply voltage (U₁₂) is higher than the first tolerance value (ΔU₁₂).
 8. The circuit configuration of one of claims 1-7, in which at least the first consumer circuit (V1) is of intrinsic and/or enhanced safety. 